Abstract

The medial amygdala (MeA) is a central hub in the olfactory neural network. It receives vomeronasal information directly from the accessory olfactory bulb (AOB) and main olfactory information largely via odor-processing regions such as the olfactory cortical amygdala (CoA). How these inputs are processed by MeA neurons is poorly understood. Using the GAD67-GFP mouse, we show that MeA principal neurons receive convergent AOB and CoA inputs. Somatically recorded AOB synaptic inputs had slower kinetics than CoA inputs, suggesting that they are electrotonically more distant. Field potential recording, pharmacological manipulation, and Ca2+ imaging revealed that AOB synapses are confined to distal dendrites and segregated from the proximally located CoA synapses. Moreover, unsynchronized AOB inputs had significantly broader temporal summation that was dependent on the activation of NMDA receptors. These findings show that MeA principal neurons process main and accessory olfactory inputs differentially in distinct dendritic compartments.

SIGNIFICANCE STATEMENT In most vertebrates, olfactory cues are processed by two largely segregated neural pathways, the main and accessory olfactory systems, which are specialized to detect odors and nonvolatile chemosignals, respectively. Information from these two pathways ultimately converges at higher brain regions, one of the major hubs being the medial amygdala. Little is known about how olfactory inputs are processed by medial amygdala neurons. This study shows that individual principal neurons in this region receive input from both pathways and that these synapses are spatially segregated on their dendritic tree. We provide evidence suggesting that this dendritic segregation leads to distinct input integration and impact on neuronal output; hence, dendritic mechanisms control olfactory processing in the amygdala.

Introduction

Despite growing interest in understanding the mechanisms of emotional processing in the amygdala, our knowledge of this brain region is largely limited to those neural circuits that process multimodal sensory information and engage in acquired emotions, particularly conditioned fear (Phelps and LeDoux, 2005; Pare and Duvarci, 2012). However, a significant proportion of the amygdala, including the medial and the cortical nuclei, are dedicated to innate emotional processes, which, particularly in rodents, heavily depend on olfaction (Stowers et al., 2013).

As a major site of convergence of the largely nonoverlapping main and accessory olfactory pathways, the MeA is well positioned to integrate chemosensory information detected by different olfactory systems (Brennan and Zufall, 2006; Martinez-Marcos, 2009). However, little is known about the neural basis of olfactory processing in this region. Data from in vivo single unit recordings (Bergan et al., 2014) and immediate early gene expressions (Samuelsen and Meredith, 2009) suggest that MeA neurons can be driven by vomeronasal but not main olfactory input. In contrast, a previous study (Licht and Meredith, 1987) showed that stimulation of either the MOB or the vomeronasal organ can drive the same neurons in the posteromedial cortical amygdala, another vomeronasal processing region adjacent to the MeA. Thus, whether individual MeA neurons receive convergent inputs from the two olfactory pathways remains unclear, particularly considering that extracellular unit activity (Licht and Meredith, 1987; Binns and Brennan, 2005; Bergan et al., 2014; Govic and Paolini, 2015) reports neuronal output without providing any information about subthreshold synaptic inputs to individual neurons. Furthermore, the physiological properties of these inputs and their synaptic organization in the MeA are little understood (Bian et al., 2008; Keshavarzi et al., 2014). Here, we studied the responses of principal neurons in the posteroventral division of the MeA (MePV) to stimulation of olfactory CoA and AOB afferents, representing the main and accessory olfactory pathways, respectively. The MePV was chosen because of its anatomical proximity to both AOB afferents and the olfactory CoA as well as the clear segregation of main and accessory olfactory bulb projections at posterior regions (Martinez-Marcos, 2009), which facilitates independent stimulation of the two inputs in slice preparations. MePV principal neurons were found to receive convergent AOB and CoA inputs that are differentially segregated on their dendritic tree. We find that, compared to CoA inputs, AOB inputs are located on the distal dendritic arbor and show a broader summation and higher output gain. These findings suggest distinct processing of main and accessory olfactory information by MeA neurons.

Materials and Methods

Slice preparation and electrophysiology.

Acute brain slices were prepared from 35- to 50-d-old male heterozygous GAD67-EGFP (Δneo) mice (referred to as GAD67-GFP mice), in which enhanced green fluorescent protein is expressed under the control of the promoter for the GABA synthesizing enzyme, GAD67 (Tamamaki et al., 2003). The exclusive use of males was designed to minimize the effect of sex and hormonal variations in the sexually dimorphic MeA (Rasia-Filho et al., 2004; Cooke and Woolley, 2005; Cooke et al., 2007). Following deep isoflurane anesthesia, mice were decapitated in accordance with the guidelines of the University of Queensland Animal Ethics Committee. Brains were rapidly removed and placed into ice-cold, oxygenated (bubbled with 95% O2/5% CO2) cutting solution containing the following (in mm): 87 NaCl, 50 sucrose, 25 glucose, 25 NaHCO3, 2.5 KCl, 4 MgCl2, 0.5 CaCl2, and 1.2 NaH2PO4. Coronal slices (300 μm thick) were prepared using a vibrating microslicer (Leica) and incubated at 35°C for 30 min in oxygenated artificial CSF (ACSF) containing the following (in mm): 118 NaCl, 10 glucose, 25 NaHCO3, 2.5 KCl, 1.3 MgCl2, 2.5 CaCl2, and 1.2 NaH2PO4. Slices were then allowed to equilibrate at room temperature for at least 30 min before being transferred to the recording chamber.

During recordings, slices were superfused with oxygenated ACSF maintained at 32−34°C. Recording electrodes (3–5 MΩ) were prepared from borosilicate glass and filled with internal solution containing the following (in mm): 135 KMeSO4, 8 NaCl, 10 HEPES, 2 Mg2-ATP, 0.3 Na3-GTP, and 0.3 EGTA (pH 7.3 with KOH; osmolarity, ∼290 mOsm). Biocytin (0.3%) was added to the internal solution in some recordings. Whole-cell patch-clamp recordings were made from the soma of GFP-negative neurons in the MePV (Bregma, −1.34 to −1.82 mm; Paxinos and Franklin, 2001) using infrared differential interference contrast video microscopy (Stuart et al., 1993) with an upright microscope (BX50WI, Olympus) equipped with fluorescence attachments. Cells with a resting membrane potential more positive than −55 mV and an access resistance >20 MΩ were discarded. Current- or voltage-clamp recordings were made using a patch-clamp amplifier (MultiClamp 700B, Molecular Devices), low-pass filtered at 6 kHz, and digitized at 20 kHz using an ITC-16 interface board (Instrutech) under the control of Axograph X (version 1.4.4, Axograph Scientific). For extracellular recordings, borosilicate glass micropipettes with a smaller tip size (5–7 MΩ), which were filled with a sodium chloride solution (3M), were used. Extracellular signals were low-pass filtered at 1–2 kHz and sampled at 10 kHz.

A theta glass or a custom-built silver-coated bipolar stimulating electrode (∼2–5 μm tip diameter, filled with ACSF) was used for electrical stimulations. AOB afferents and the olfactory CoA were alternately stimulated (interval, 1 s; pulse duration, 100–300 μs; frequency, 0.1–0.2 Hz) by two stimulating electrodes, placed in the ventral surface of the MeA molecular layer (Bian et al., 2008; Keshavarzi et al., 2014) and in the posterolateral or anterior CoA (Bregma, −1.34 to −1.82 mm; Paxinos and Franklin, 2001), respectively (Fig. 1A). The molecular layer of the MeA is a well-defined cell-sparse region located at its external ventromedial borders (Keshavarzi et al., 2014, their Fig. S1A) and contains dense axonal projections from mitral/tufted cells of the AOB (von Campenhausen and Mori, 2000; Mohedano-Moriano et al., 2007). Stimulation intensities (10–40 V) were adjusted to evoke EPSPs of either minimal or ∼20–50% maximal amplitude. To measure the paired-pulse ratio (PPR), two successive stimuli were delivered at a 100 ms interval. To evoke a train of EPSPs, short trains of stimuli (5–10 stimuli at 50 Hz) were delivered at 0.1–0.2 Hz.

Pharmacology.

Tetrodotoxin (TTX; 1 μm) was pressure applied focally (500 kPa; 300 ms) with a glass electrode (5–6 MΩ) attached to a Picospritzer II (General Valve). The electrode was placed close to the distal dendritic branches in the molecular layer, which were visualized by addition of the fluorescent dye Alexa Fluor 568 (Invitrogen; 10 μm) to the internal solution. To monitor the flow of TTX in the slice, Alexa Fluor 568 was also included in the puffing electrode together with TTX. The position of the puffing electrode and the bath circulation were adjusted to allow the flow of TTX toward the suction and away from the tissue and stimulation sites. All other drugs were bath applied at the following concentrations (in μm): 50 baclofen (Sigma), 30 d-APV (Sigma), 10 NBQX (Tocris), and 100 picrotoxin (Sigma).

Morphology reconstruction.

Morphology of some recorded neurons (n = 10) was visualized using streptavidin-conjugated fluorescent dyes as described previously (Keshavarzi et al., 2014). Briefly, slices containing biocytin-filled cells were fixed in 4% paraformaldehyde in 0.1 m phosphate buffer (PB), pH 7.4, for 1 h. Following washes in 0.1 m PBS containing 0.3% Triton X-100 (three times, 10 min each), slices were incubated in streptavidin-conjugated Alexa Fluor 568 or 647 (1:1000; Invitrogen) for 5 h. They were then washed with PBS and mounted with 50% glycerol in PBS. Fluorescent images were acquired using a confocal microscope, and morphology reconstructions were made with Neurolucida (MBF Bioscience).

Two-photon calcium imaging.

The green fluorescent calcium indicator Oregon Green BAPTA-1 (OGB-1; 100 μm; Invitrogen) and the red fluorescent calcium-insensitive Alexa Fluor 594 (30 μm; Invitrogen) were added to the internal solution (made without EGTA). After establishing whole-cell configuration, dyes were allowed to diffuse into the dendrites for at least 10 min before starting calcium imaging. Subthreshold AOB or CoA EPSPs were evoked by 50 Hz trains of electrical stimulation, and data were excluded if synaptically driven spikes were observed. Two-photon images of OGB-1 and Alexa Fluor 594 were acquired using a Zeiss LSM 710 equipped with a Chameleon multiphoton imaging laser (Coherent) at an excitation wavelength of 810 nm. The emitted light was split with a dichroic filter, bandpass filtered (green channel, 500–550 nm; red channel, 565–610 nm), and detected with separate nondescanned detectors. Fluorescence images were obtained in line-scan mode (200–300 Hz) at a resolution of 10–20 pixels/μm. Line scans were performed orthogonal to the dendritic shaft and, in some cases, included the attached spines. Calcium signals in spines and the parent dendritic shafts were pooled. Image analysis was performed off-line using custom-written procedures in Fiji (Schindelin et al., 2012). The z-stack images were taken at the conclusion of the experiments and used to measure the distance of scanned sites from the soma. Calcium signals were quantified as the change in the green fluorescence (ΔG) divided by the red fluorescence (R). Only ΔG/R changes larger than three times the standard deviation of the baseline noise were considered as calcium transient. ΔG/R traces were plotted in Axograph, averaged (three to five traces), and postfiltered at 10–20 Hz to improve visibility.

Electrophysiological analysis.

Electrophysiological analysis was performed using Axograph X. For measurements of synaptic events, ensemble-averaged responses from a minimum of five sweeps were used. The onset of evoked EPSCs was measured as the delay between the stimulus artifact and the foot of the EPSC. The EPSC decay time constant was measured by a single exponential fit to the current decay at −60 mV holding potential. The EPSC rise time was measured from 10 to 90% of the EPSC peak amplitude. The PPR was calculated by dividing the peak amplitude of the second EPSP to that of the first. EPSP summation was measured as the area under the EPSP train waveform (integral of EPSP trains) normalized to that of a single EPSP.

Statistical analysis.

Statistical comparisons and graphs were made using Prism 6 (GraphPad). Data are presented as means ± SEM. Unless stated otherwise, a Student's two-tailed t test (paired or unpaired) or a two-way ANOVA with a Bonferroni correction was used for comparisons between groups. Differences were considered statistically significant at p < 0.05.

We first tested this hypothesis using extracellular field recordings. If AOB synapses were distal and CoA synapses proximal, the evoked field potentials would have a laminar profile, with the current sink of the AOB input in the molecular layer and that of the CoA input in the cellular layer (Colbert and Levy, 1992). Extracellular field recordings were made at different depths of the MePV by moving the recording electrode from the molecular to the cellular layer while AOB or CoA afferents were electrically stimulated (Fig. 3A). Field EPSPs (fEPSPs) could be evoked by both AOB and CoA stimulation and were fully blocked by NBQX (10 μm; n = 4; Fig. 3B,C), confirming their synaptic origin. In agreement with a differential anatomical location of these inputs, fEPSPs evoked by AOB and CoA stimulation had opposite polarities (Fig. 3B,D); the sink (negativity) of AOB fEPSPs (peak, −117 ± 16 μV; n = 14) was in the molecular layer, whereas that of the CoA input (peak, −79 ± 14 μV; n = 10) was in the cellular layer (Fig. 3). Interestingly, the polarity of both fEPSPs reversed at ∼100–150 μm from the ventral surface of the MeA (Fig. 3D,E), corresponding to the depth of the molecular layer (Fig. 3A; Keshavarzi et al., 2014). These data suggested that AOB and CoA synapses have distinct spatial distributions in MeA principal neurons. To directly confirm this prediction, we used focal pharmacology on individual neurons to test whether disruption of synaptic transmission at distal dendrites could block the AOB but not the CoA synaptic inputs. Whole-cell recordings were made from MePV principal neurons and their dendrites visualized by addition of Alexa Fluor 568 in the internal solution. Focal pressure ejection of TTX (1 μm) onto distal dendritic branches in the molecular layer (Fig. 4A) substantially blocked AOB EPSCs (81 ± 0.6% block), with minimal effect on the CoA input (8 ± 0.5% block; n = 8; AOB vs CoA, p < 0.0001; Fig. 4B,C), showing that these two inputs are differentially segregated on individual neurons.

AOB and CoA field potentials have different spatial profiles in the MePV. A, Schematic of field recordings. The extracellular electrode was moved from ventral [1 in the molecular layer (lm)] to dorsal [4 in the cellular layer (lc)] locations while AOB and/or CoA afferents were stimulated. MePD, Posterodorsal medial amygdala; ot, optic tract. B, Field potentials evoked by electrical stimulation of AOB (red) and CoA (blue) afferents in the presence of picrotoxin (100 μm). Traces are averaged responses recorded extracellularly in the cellular and molecular layers. Both recordings were made in the same slice. C, The same recordings as in B, after bath application of NBQX (10 μm). D, Representative averaged AOB and CoA fEPSPs recorded at locations shown in A. E, The peak amplitude of fEPSPs (mean ± SEM) at each location, marked with pink and blue lines in D, was plotted against the distance of the recording electrode from the ventral surface of the MeA. n is the number of recordings (one slice was recorded in each mouse, with a total of 6 slices). In three slices, only AOB fEPSPs were recorded. In all other slices with CoA field recordings, AOB fEPSPs were also evoked with a second stimulating electrode.

Ca2+ transients evoked by AOB and CoA inputs are confined to segregated dendritic locations. A, Compressed z-stack two-photon image of an Alexa Fluor 594–filled GFP-negative MePV neuron scanned for AOB-evoked Ca2+ transients. The sites of line scan on a ventrally extending dendrite are labelled (1–4). B, A 50 Hz train of EPSPs evoked by electrical stimulation of AOB afferents (top) and simultaneous recordings of Ca2+ transients (1–4; plotted as ΔG/R) at dendritic locations shown in A. C, A 100 Hz train of APs (top) evoked by somatic current injection and simultaneous Ca2+ signals (1–4) recorded at the same dendritic sites shown in A. D, Compressed z-stack two-photon image of a GFP-negative MePV neuron scanned for CoA-evoked Ca2+ transients. The sites of line scan on a laterally extending dendrite are labelled (1–4). E, A 50 Hz train of EPSPs evoked by electrical stimulation of the posterolateral CoA (top) and Ca2+ transients (1–4) recorded at dendritic locations shown in D. F–H, Population data of calcium transients evoked by 50 Hz trains of AOB (F) and CoA (G) EPSPs and a 100 Hz train of backpropagating action potentials (H) plotted against the distance from the soma. I, ΔG/R values were binned at 50 μm distances from the soma, and the averaged ΔG/R values, calculated at each bin and normalized to the largest value, were plotted against the distance from the soma (mean ± SEM). V, Ventral; M, medial. n, Number of cells. Scale bars: 20 μm.

The location of synapses on the dendritic arbor is known to shape the integration of synaptic inputs, their impact on neuronal output, and their plasticity (Magee, 2000; Williams and Stuart, 2003; London and Häusser, 2005; Kampa et al., 2007). To test whether the segregated AOB and CoA synaptic inputs integrate differently at the soma, we compared the temporal summation of asynchronous EPSPs at these two synapses. Trains of AOB and CoA EPSPs (50 Hz) were alternatively evoked at rest (−69 ± 2 mV) and summation calculated as the integral of waveform of the EPSPs normalized to that of a single EPSP. Stimulation intensities were adjusted to evoke individual EPSPs of either minimal (peak EPSP, AOB, 2 ± 0.2 mV; CoA, 3 ± 0.5 mV; n = 8) or ∼50% maximal amplitude (peak EPSP, AOB, 6 ± 0.6 mV; CoA, 6 ± 0.2 mV; n = 8); however, because summation was similar at both intensities, data were pooled. Temporal summation of AOB EPSPs was significantly greater than that of CoA EPSPs (20 ± 3 vs 7 ± 1; n = 16; p < 0.01; Fig. 6), which either failed to summate or showed little summation (Fig. 6A,B). Consequently, AOB EPSPs depolarized the soma closer to the AP threshold than did the CoA EPSPs (peak EPSP train-amplitude first EPSP, AOB, 6 ± 1 mV; CoA, 1 ± 0.6 mV; n = 16; p < 0.001) and were more likely to discharge the cell (spikes/EPSP train, 1 ± 0.3 vs 0; n = 16; p < 0.05; Fig. 6A). The larger temporal summation of AOB EPSPs can be partly explained by the slow decay of distal inputs as a result of passive dendritic filtering (Rall, 1964, 1967). Active dendritic conductances, such as voltage-gated Na+ and Ca2+ channels and NMDAR, may also amplify the integration and gain of distal inputs (Schiller et al., 1997; Golding and Spruston, 1998; Larkum et al., 2009; Branco and Häusser, 2011). To test the contribution of NMDARs to temporal integration of AOB and CoA inputs, NMDARs were blocked using d-APV (30 μm; n = 5). Application of d-APV substantially suppressed the summation of AOB EPSPs and reduced the magnitude of somatic depolarization (Fig. 6B–D), but had little effect on CoA input summation, suggesting that NMDARs substantially enhance the integration and gain of AOB inputs.

It should be noted that the electrical stimulation in the molecular layer used in this study might have inadvertently recruited other fibers and contaminated these inputs. This could have particularly affected the AOB input, which was evoked by stimulating the afferent fibers in the molecular layer of the MeA, rather than by direct stimulation of the AOB. However, previous anatomical data from comprehensive neural tracing experiments in the mouse brain show that afferents in the molecular layer are dominated by those arising in the AOB, and the majority of other afferents to the MeA do not contact the superficial molecular layer (Oh et al., 2014; Allen Mouse Brain Connectivity Atlas, http://connectivity.brain-map.org). Moreover, the small MOB projections that are present in the molecular layer mostly terminate in the rostral MeA and are negligible in slices containing the MePV (von Campenhausen and Mori, 2000; Pro-Sistiaga et al., 2007; Kang et al., 2009; Cádiz-Moretti et al., 2014; see also experiments 120812686 and 146921849 in the Allen Mouse Brain Connectivity Atlas, http://connectivity.brain-map.org). Hence, for the MePV, the contribution of non-AOB inputs when stimulating in the molecular layer would be minimal.

Pathway-specific spatial segregation of excitatory synapses on dendrites has been described previously in cortical and hippocampal pyramidal neurons (Amaral, 1993; Haberly, 2001; Spruston, 2008), but not in the amygdala, which, with the exception of the CoA, lacks a clear laminar organization. Thus far, the only evidence for afferent-specific segregation of excitatory synapses in the amygdala has been at the level of neighboring, but distinct, dendritic spines on projection neurons of the lateral amygdala (Humeau et al., 2005). Interestingly, our data suggest that the organization of olfactory input to MeA principal cells is similar to that for layer II/III principal neurons in the piriform cortex. Thus, afferents from the main olfactory bulb carried in the lateral olfactory tract (LOT) synapse onto the distal apical dendrites in layer Ia of the piriform cortex (Haberly, 2001), resembling AOB synapses on distal dendrites of MePV principal cells in the molecular layer. Associational synapses, on the other hand, are formed closer to the soma in deeper layers of the piriform cortex (Johnson et al., 2000), comparable to CoA synapses on proximal dendritic domains of MePV neurons. Consistent with our findings in the MePV, in layer II/III pyramidal neurons, somatic recordings of LOT and associational inputs have different kinetics, with slower rise and decay times for the distal LOT input, due to greater electrotonic filtering (Franks and Isaacson, 2005). Moreover, differences in short-term plasticity between LOT and associational inputs to the semipyramidal cells of the piriform cortex (Bower and Haberly, 1986; Franks and Isaacson, 2005; Suzuki and Bekkers, 2006) were also found between AOB and CoA inputs, with paired-pulse facilitation at AOB but not CoA synapses. Together, these findings indicate that the olfactory processing circuitry in the MeA is homologous to that in the piriform cortex.

Considering that AOB synapses provide the major flow of sensory information to the MeA, their electrotonically disadvantaged location on distal dendrites raises the question of whether any compensatory mechanism is used to amplify their output gain. A number of passive and active dendritic properties have been suggested to enhance the efficacy of distal synapses (Schiller et al., 1997; Magee and Cook, 2000; Williams and Stuart, 2002; Larkum et al., 2009), and even to confer on them a larger impact on the soma than proximal synapses (Branco and Häusser, 2011). Excitatory inputs to distal cortical dendrites, for instance, were shown to integrate over a wider temporal window and be amplified with a higher gain than proximal inputs, largely due to the recruitment of distal NMDARs (Branco and Häusser, 2011). Our results demonstrating NMDAR-dependent broad temporal summation and a higher output gain of distal AOB inputs are in line with these findings. Moreover, consistent with larger NMDAR activation by unsynchronized AOB inputs, Ca2+ transients were more readily evoked by AOB than CoA EPSPs. Interestingly, our finding that successive AOB inputs are more effective than CoA inputs in discharging MeA neurons also corresponds to the previous in vivo data showing that these neurons can be driven by stimulation of the vomeronasal organ, but not the main olfactory epithelium (Bergan et al., 2014).

The NMDAR dependence of AOB input summation may be explained by the high input impedance at distal synapses, which would cause a relatively larger local dendritic depolarization at these sites and release the magnesium block of NMDARs (Nowak et al., 1984; Schiller et al., 1997; Larkum et al., 2009; Branco and Häusser, 2011). Moreover, other contributing mechanisms may include differences in the number, density, or subunit composition of NMDARs at these two synapses (Otmakhova et al., 2002; Nicholson et al., 2006). Previous data suggest that, in contrast to synapses in the MOB, a large number of AOB synapses are rich in the GluN2B subunit of NMDARs (Dani et al., 2010). Whether similar rules apply to AOB and CoA synapses on MeA neurons awaits future studies using dendritic recording (Andrasfalvy and Magee, 2001) or nanoscale imaging of labeled glutamate receptors at these synapses (Nicholson et al., 2006; Dani et al., 2010). Moreover, potential spillover of glutamate to neighboring extrasynaptic NMDARs, which is thought to promote the generation of dendritic NMDA spikes (Chalifoux and Carter, 2011), may also play a part. Finally as shown in Figure 1, both inputs evoke clear inhibitory responses, mediated by local feedforward inhibition (Keshavarzi et al., 2014). Although not tested in the current study, differential recruitment of these inhibitory inputs will also likely play a role in processing these inputs in vivo.

What is the functional outcome of this wiring for olfactory processing in the MeA? Previous studies in pyramidal neurons have shown that distal synapses can impact the gain and plasticity of proximal inputs (Remondes and Schuman, 2002; Dudman et al., 2007; Han and Heinemann, 2013). In CA1 pyramidal neurons, for instance, closely timed activation of the distal perforant path and the proximal Schaffer-collateral synapses induces potentiation of the latter (Dudman et al., 2007). Thus, it is likely that, through a similar mechanism, an association between main and accessory olfactory inputs will be formed in MeA principal neurons, leading to odor-evoked responses driven by pheromonal cues. In line with this hypothesis, intact accessory olfactory signaling was found to be necessary for normal mating behavior in sexually inexperienced male hamsters, whereas once mated or preexposed to female chemosignals, the main olfactory system alone was sufficient (Meredith, 1986; Westberry and Meredith, 2003), indicating that odors can be learnt in association with pheromones through experience. We thus propose that future studies address this hypothesis by investigating the interaction between main and accessory olfactory inputs at the level of individual MeA neurons and in behavior.

Footnotes

This work was supported by grants from the National Health and Medical Research Council of Australia and the Australian Research Council (P.S.) and scholarship from the University of Queensland (S.K.). We thank Alan Woodruff for comments on this manuscript.

The authors declare no competing financial interests.

Correspondence should be addressed to Pankaj Sah,
Queensland Brain Institute, Building 79, The University of Queensland, St. Lucia, QLD 4072, Australia.pankaj.sah{at}uq.edu.au

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